KR20220036144A - Anion generating LED lamp with harmful electromagnetic wave attenuation function - Google Patents

Abstract

The purpose of the present invention is to provide a negative ion generating LED lighting lamp with a harmful electromagnetic wave attenuation function that can attenuate harmful electromagnetic waves generated when artificial negative ions are generated in a negative ion generating LED lighting lamp.
The negative ion generating LED lighting of the present invention includes an LED module board on which a plurality of LED chips are mounted, a negative ion generator that generates negative ions when high voltage is applied, a first DC power source for supplying DC power to the LED module board, and a DC power supply to the negative ion generator. It is configured to include a second DC power supply unit for supplying power, and a sub-band pulse inductor for generating sub-band electromagnetic waves corresponding to the positive-band electromagnetic waves generated from the negative ion generator.

Description

Anion generating LED lamp with harmful electromagnetic wave attenuation function}

The present invention relates to negative ion generating LED lighting, and more specifically, to negative ion generating LED lighting having a harmful electromagnetic wave attenuation function that cancels out harmful electromagnetic waves emitted when negative ions are generated through electromagnetic induction.

Lighting, which was previously used simply as a means of lighting, has recently become a part of the interior, emitting light in various patterns. Lighting devices suitable for indoor interiors include incandescent light bulbs or light bulb-type fluorescent lights that are almost similar in appearance to incandescent light bulbs, have socket compatibility, and are widely used as energy-saving equipment. Recently, LED lighting is replacing traditional lighting such as incandescent bulbs and fluorescent lamps. LED lighting not only consumes less power and is more efficient, but its service life is also almost semi-permanent compared to incandescent bulbs and fluorescent lamps, so it is gradually gaining popularity as the main living lighting. I'm receiving it.

Meanwhile, as LED lighting has become the mainstream lighting, various types of products have emerged with many advantages such as economic efficiency and efficiency of LED, and they can clean indoor air as well as indoor interior, remove chemicals that cause sick building syndrome, etc. Products with various functions were also released.

In general, negative ions purify the air by neutralizing and precipitating gaseous pollutants such as nitrogen oxides, sulfur oxides, hydrocarbons, carbon monoxide and carbon dioxide, and volatile organic compounds such as formaldehyde, toluene and cigarette smoke, and remove germs, bacteria and bad odors. It is known to help prevent and treat various chronic diseases such as neuralgia, asthma, and insomnia, and to revitalize the human body, relieve fatigue, relieve stress, and promote learning. Recently, lighting products equipped with negative ion generators have been released to achieve the negative ion effect. There are many advantages to using a negative ion generator attached to a lighting lamp, such as no need to clean the filter, no hassle of replacement, no cost, no noise, and no restrictions on installation location due to its small size.

As a technology for equipping lighting with a negative ion generator, various technologies have emerged, such as Patent Registration No. 757843, “Lighting equipment for generating negative ions,” and Patent Registration No. 1738504, “LED lighting equipped with a negative ion generator.” However, in order to generate negative ions, a high voltage must be generated using electromagnetic induction and applied to the negative ion generator. As a result, harmful electromagnetic waves are unnecessarily generated, and these harmful electromagnetic waves are not only transmitted to the human body, but also to the circuit and surroundings of the lighting device equipped with the negative ion generator. It directly or indirectly affects electronic devices, causing problems that cause malfunction or shorten the lifespan of electronic devices.

The present invention was created to solve the above problems, and the purpose of the present invention is to provide a device with a harmful electromagnetic wave attenuation function that can attenuate harmful electromagnetic waves generated when artificial negative ions are generated in negative ion generating LED lighting. The purpose is to provide negative ion generating LED lighting.

The negative ion generating LED lighting with a harmful electromagnetic wave attenuation function according to the present invention includes an LED module substrate on which a plurality of LED chips are mounted; A negative ion generator that generates negative ions when high voltage is applied; A first DC power supply for supplying DC power to the LED module board; a second DC power supply for supplying DC power to the negative ion generator; It is characterized by comprising a sub-band pulse inductor for generating sub-band electromagnetic waves corresponding to the positive-band electromagnetic waves generated from the negative ion generator.

Preferably, the negative ion generator includes: a DC power input unit to which a DC voltage is applied from a second DC power supply unit; An oscillator that oscillates and amplifies the DC voltage input from the DC power input unit; A transformer that converts and outputs the voltage amplified through the oscillator according to a preset voltage conversion ratio; It is comprised of a high voltage output unit that generates a high voltage by doubling the output voltage of the secondary side of the transformer, and the sub-band pulse inductor is connected to the high voltage output unit.

Preferably, a condenser is provided in the high voltage output unit, and the output from the sub-band pulse inductor and the secondary output of the transformer are combined through the condenser and then output.

The negative ion generating LED lighting according to the present invention generates anti-phase electromagnetic waves corresponding to the positive-phase electromagnetic waves generated when artificial negative ions are generated in the negative ion generator mounted on the LED lighting, canceling each other out to attenuate harmful electromagnetic waves. It can block the effects of electromagnetic waves on the human body, and can block the effects on circuits such as LED lighting equipped with negative ion generators and surrounding electronic devices, thereby solving the problem of electronic devices malfunctioning or shortening their lifespan.

Figure 1 is a diagram schematically showing the configuration of a negative ion generating LED light according to the present invention.
Figure 2 is a block diagram schematically showing the internal circuit configuration of the negative ion generating LED lighting according to the present invention.
Figure 3 is a circuit diagram schematically showing the internal configuration of the negative ion generator of the negative ion generating LED lighting according to the present invention.
Figure 4 is an explanatory diagram to explain the principle of attenuation of harmful electromagnetic waves.

Figure 1 is a diagram illustrating an example of a negative ion generating LED lighting lamp 10 equipped with a harmful electromagnetic wave attenuation function according to an embodiment of the present invention.

As shown in FIG. 1, a negative ion generating LED lighting lamp (hereinafter referred to as an 'LED lighting device') with a harmful electromagnetic wave attenuation function (10) is an LED module substrate (11) on which a plurality of LED chips (110) are mounted. , supplies direct current power to the negative ion generator 12, the LED module board 11, and the negative ion generator 12, and includes a control circuit unit 13 for controlling the negative ion generator 12 and the LED module board 11.

The LED module board 11, the negative ion generator 12, and the control circuit 13 are all fixedly installed within the body 15 of the lighting device, and the DC power supply of the control circuit 13 is supplied with a commercial AC power source (for example, AC 220V). ), and the DC power supply units 131 and 132 are configured to receive AC voltage from the AC power source and supply the DC voltage required for the LED module board 11 and the negative ion generator 12.

Figure 2 is a block diagram schematically showing the control circuit unit 13 of the negative ion generating LED lighting lamp 10.

As shown in FIG. 2, the control circuit unit 13 includes a first DC power supply unit 131 including a DC constant voltage circuit for supplying DC power to the LED module board 11, and a DC power supply required for the negative ion generator 12. It includes a second DC power supply unit 132 to supply a negative ion generator 12 and a microcomputer 130 to control the LED module, and a sub-band pulse induction unit 1321 to attenuate harmful electromagnetic waves generated from the negative ion generator. It further includes.

The first DC power unit 131 is configured to receive AC power from an AC power source and output DC power, specifically a DC constant voltage of 36V and 1.2A, and the second DC power unit 132 is configured to receive AC power from the AC power source. It is configured to receive input and output DC power, specifically 24V, 1.2A DC constant voltage.

The first and second DC power units 131 and 132 are configured to use two constant voltage circuits that each output different voltages, but the present invention is not limited thereto and, if necessary, a DC-DC converter (DC-DC converter) It may be configured to output different voltages using , or may be configured to output the same voltage.

In addition, although not shown, each DC power supply unit may further include an overvoltage prevention circuit or a ground circuit unit to prevent overvoltage suddenly applied from the outside.

The voltage converted to DC through the first DC power supply unit 131 is supplied to the LED module board 11 so that the LED chip can perform a light-emitting operation, but between the first DC power supply unit 131 and the LED module board 11 By installing the switch S1, the switch S1 is configured to be blocked and connected by the microcomputer 130, so that the ON or OFF of the LED module can be controlled.

The voltage converted to DC through the second DC power supply unit 132 is supplied to the negative ion generator 12 through a noise filter so that the negative ion generator can operate, but between the second DC power supply unit 132 and the negative ion generator 12 By installing the switch S2, the switch S2 is configured to be blocked and connected by the microcomputer 130, so that the ON or OFF of the negative ion generator 12 can be controlled.

In addition, as shown in Figure 2, according to the present invention, a sub-band pulse inducing unit 1321 is provided between the second DC power supply unit 132 and the negative ion generator 12, and the sub-band pulse inducing unit 1321 is a negative ion generator ( 12) It is configured to generate a sub-band pulse frequency that has an anti-phase relationship with the normal-band electromagnetic wave generated by the electromagnetic induction type boosting circuit built in.

Figure 3 is a circuit diagram simply showing the connection between the sub-band pulse inducing unit 1321 and the negative ion generator 12. As shown in FIG. 3, the negative ion generator 12 receives DC voltage from the second DC power supply unit 132 through the DC voltage input terminal 121, and the input DC voltage is amplified and amplified through the oscillator 122. The converted voltage is converted through a transformer (T1) with a preset voltage conversion ratio, and the converted voltage is doubled by the high voltage output terminal 125 connected to the secondary side of the transformer (T1).

Specifically, when a DC voltage of 24V is first applied from the second DC power supply unit 132, the base current of the transistor (Tr) is applied in the emitter direction and the current applied to the primary side of the transformer (T1) is applied to the transistor (Tr). is applied from the collector to the emitter and the oscillation is amplified. At the same time, when the capacitor (C) is fully charged, it is biased to the base of the transistor (Tr) by the resistor (R). In this way, the current oscillated and amplified through the transistor Tr is boosted by repeatedly charging and discharging the capacitor, and the boosted current is output to the secondary side of the transformer T1.

In other words, the voltage on the primary side of the transformer (T1) is always turned on/off by the oscillator 122 and is oscillated and amplified. This amplified voltage is applied to the transformer (T1), and the transformer (T1) receives the amplified voltage. The voltage is boosted according to the set voltage conversion ratio and output to the secondary side.

It is desirable for the boosting voltage to be generated below 5,000V. If it exceeds 5,000V, excessive energy collides with oxygen molecules, causing them to fall into negative ion molecules, and the remaining excess energy combines with other oxygen molecules to create ozone. This is because excessively high voltage voltage (approximately 5,000-6,500 V) decomposes and ionizes nitrogen molecules, which are more stable than oxygen molecules, and can lead to a dangerous situation in which highly toxic nitrogen compounds are created.

Additionally, in the above-described circuit, the sub-band pulse inducing unit 1321 is connected to the front end of the condenser C2 provided between the second DC power supply unit 132 and the secondary output of the transformer T1. As shown, the sub-band pulse inducing unit 1321 operates to generate an electromagnetic wave pulse of an anti-phase with respect to the electromagnetic wave pulse applied at the output voltage of the transformer T1.

In other words, the output terminal voltage of the transformer (T1) generates an electromagnetic wave with a magnitude of Q in a certain frequency band (H) due to a predetermined voltage conversion ratio or inductance. In the present invention, considering the characteristics of electromagnetic waves, an electromagnetic wave pulse with a magnitude of -Q is generated in a certain frequency band (H) in which electromagnetic waves are generated, and the electromagnetic wave pulse in the sub-band generated in this way is an electromagnetic wave pulse with a positive band. are combined and cancel each other out through the condenser (C2).

Figure 4 is a graph showing the offset relationship between electromagnetic waves generated by electromagnetic induction of a transformer and electromagnetic waves generated by a sub-band pulse inductor. As shown in FIG. 4, an electromagnetic wave pulse with similar waveform characteristics to an electromagnetic wave in the frequency band of the electromagnetic wave generated by electromagnetic induction of the transformer is generated through the electromagnetic wave pulse induction unit 1321 and output through the condenser C2. As a result, an output with a final attenuated electromagnetic wave waveform can be obtained.

The above description is an illustrative description of the present invention, and the embodiments published in the specification are not intended to limit the technical idea of the present invention, but are for illustrative purposes, so those skilled in the art will understand the present invention. Various modifications and variations will be possible without departing from the technical idea of . Therefore, the scope of protection of the present invention should be interpreted based on the matters stated in the claims, and technical matters within the equivalent scope thereof should also be interpreted as being included in the scope of rights of the present invention.

10: Negative ion generating LED lighting
11: LED module board
12: Negative ion generator 121: DC voltage input terminal
122: Oscillator 125: High-pressure output stage
13: control circuit unit 130: microcomputer
131: first DC power unit 132: second DC power unit
1321: Sub-band pulse induction unit
15: LED lighting body

Claims (3)

An LED module board on which a plurality of LED chips are mounted;
A negative ion generator that generates negative ions when high voltage is applied;
A first DC power supply unit for supplying DC power to the LED module board;
a second DC power supply for supplying DC power to the negative ion generator;
a sub-band pulse inducer for generating sub-band electromagnetic waves corresponding to the positive-band electromagnetic waves generated from the negative ion generator;
A negative ion generating LED lighting lamp with a harmful electromagnetic wave attenuation function, characterized in that it includes.
The method of claim 1, wherein the negative ion generator,
a DC power input unit to which a DC voltage is applied from the second DC power supply unit;
an oscillator that oscillates and amplifies the DC voltage input from the DC power input unit;
a transformer that converts and outputs the voltage amplified through the oscillator according to a preset voltage conversion ratio;
a high voltage output unit that generates a high voltage by doubling the secondary output voltage of the transformer;
Including,
A negative ion generating LED lighting lamp with a harmful electromagnetic wave attenuation function, wherein the sub-band pulse inductor is connected to a high voltage output unit.
According to paragraph 2,
A condenser is provided in the high voltage output unit, and the output from the sub-band pulse inductor and the secondary output of the transformer are combined through the condenser and then output. An LED lighting lamp that generates negative ions with a harmful electromagnetic wave attenuation function.